Review of Recent Studies on the PRISM FFAG

1. Review of Recent Studies onthe PRISM FFAG J. Pasternak, Imperial College London/RAL STFC on behalf of the PRISM Task Force J. Pasternak

2. Outline • Introduction. • PRISM/PRIME experiment. • PRISM Task Force initiative. • Proton beam • Pion production and capture. • Muon transport. • Injection/extraction. • Reference PRISM FFAG ring design and its modifications. • Alternative ring designs. • Today PRISM session. J. Pasternak

3. Introduction ? ? • Charge lepton flavor violation (cLFV) is strongly suppressed in the Standard • Model, its detection would be a clear signal for new physics! • Search for cLFV is complementary to LHC. • The μ-+ N(A,Z)→e- + N(A,Z) seems to be the best laboratory for cLFV. • The background is dominated by beam, which can be improved. • The COMET and Mu2e were proposed and PRISM/PRIME is the next generation experiment. Does cLFV exists? Simulations of the expected electron signal (green). J. Pasternak

4. Layout of the PRISM/PRIME PRISM - Phase Rotated Intense Slow Muon beam Single event sensitivity – 3×10-19 The PRISM/PRIME experiment based on FFAG ring was proposed (Y. Kuno, Y. Mori) for a next generation cLFV searches in order to: - reduce the muon beam energy spread by phase rotation, - purify the muon beam in the storage ring. J. Pasternak

5. PRISM parameters J. Pasternak

6. PRISM Task Force . The Task Force areas of activity:- the physics of muon to electron conversion,- proton source,- pion capture,- muon beam transport,- injection and extraction for PRISM-FFAG ring,- FFAG ring design including the search for a new improved version,- FFAG hardware systems R&D. • The aim of the PRISM Task Force: • Address the technological challenges in realising an FFAG based muon-to-electron conversion experiment, • Strengthen the R&D for muon accelerators in the context of the Neutrino Factoryand future muon physics experiments. Members: J. Pasternak, Imperial College London, UK/RAL STFC, UK (contact: j.pasternak@imperial.ac.uk) L. J. Jenner, A. Kurup, Imperial College London, UK/Fermilab, USA M. Aslaninejad,Y. Uchida, Imperial College London, UK B. Muratori, S. L. Smith, Cockcroft Institute, Warrington, UK/STFC-DL-ASTeC, Warrington, UK K. M. Hock, Cockcroft Institute, Warrington, UK/University of Liverpool,UK R. J. Barlow, Cockcroft Institute, Warrington, UK/University of Manchester, UK C. Ohmori, KEK/JAEA, Ibaraki-ken, Japan H. Witte, T. Yokoi, JAI, Oxford University , UK J-B. Lagrange, Y. Mori, Kyoto University, KURRI, Osaka, Japan Y. Kuno, A. Sato, Osaka University, Osaka, Japan D. Kelliher, S. Machida, C. Prior, STFC-RAL-ASTeC, Harwell, UKM. Lancaster, UCL, London, UK You are welcome to join us! J. Pasternak

7. PRISM Task Force Design Strategy Option 1: Adopt current design and work out injection/extraction, and hardware Option 2: Find a new design They should be evaluated in parallel and finaly confronted with the figure of merit (FOM) (number of muons delivered to target/cost). Requirements for a new design: • High transverse acceptance (at least 38h/5.7v [Pi mm] or more). • High momentum acceptance (at least ± 20% or more). • Small orbit excursion. • Compact ring size (this needs to be discussed). • Relaxed or at least conserved the level of technical difficulties. for hardware (kickers, RF) with respect to the current design. J. Pasternak

8. Proton Beam for PRISM/PRIME Two methods established – BASED on LINAC or SYNCHROTRON acceleration. H- linac Accumulator Ring Booster Compressor Ring Main Synchrotron H-linac followed by the accumulator and compressor High power synchrotrons produce many bunches and extract one by one (proposed at J-PARC). • PRISM/PRIME needs a short bunch (~10 ns)! • Where could it be done ?: • at Fermilab(possibly at the Projext-X muon line)? • at J-PARC, • at CERN (using SPL), • at RAL (MW ISIS upgrade could be adopted). In general any Neutrino Factory Proton Driver would work for PRISM! Please see L. Jenner’s talk. J. Pasternak

9. Pion Production • 2 (4) MW proton beam power. • Beam energy 3-8 GeV. • Proton bunch length at • the target ~10 ns. • Heavy metal (W, Au, Pt, Hg) target. • 12 (20) T SC pion capture solenoid. • Backward pion collection. Au target simulations using MARS Please see A. Alekou’s talk for alternative. J. Pasternak

10. Pion/Muon Transport Negativevertical deflection corrector Vertical dispersionsuppressor Vertical Septum Vertical dispersion matching Quad matching Kickers Bend solenoidal channel in „Pi/2–Pi/2” configuration (to compensate the drift) DispersionCreator (Orbit matching) Solenoidal matching cell FFAG line for betatron matching (J-B. Lagrange) The goal - 70% muon transport efficiency! This design is under studies within the PRISM Task Force. J. Pasternak

11. Preliminary PRISM kicker studies H. Witte, M. Aslaninejad, J. Pasternak length 1.6 m B 0.02 T Aperture: 0.95 m x 0.5 m Flat top 40 /210 ns (injection / extraction) rise time 80 ns (for extraction) fall time ~200 ns (for injection) Wmag=186 J L = 3 uH (preliminary) Imax=16 kA J. Pasternak

12. PRISM Pulse Formation 80 kV Impedance 3 Ohm Kicker subdivided into 8 smaller kickers Travelling wave kicker Each sub-kicker has 5 sections 1 plate capacitor per section J. Pasternak

13. Reference Design Parameters – A. Sato V per turn ~2-3 MV p/p at injection =± 20% p/p at extraction =± 2% (after 6 turns ~ 1.5 us) h=1 J. Pasternak

14. Reference design modifications for Injection/Extraction • In order to inject/extract the beam • into the reference design, special magnets • with larger vertical gap are needed. • This may be realised as an insertion • (shown in red below). • The introduction of the insertion breaks • the symmetry but this does not limits the • dynamical acceptance, if properly done! rad R[m] rad y[m] J. Pasternak

15. Phase rotation calculations in PRISM ring Injected bunch Extracted bunch Phase rotation for 68 MeV/c reference muon • An RF system has been constructed and tested. • Very large (~1.7 m X 1.0 m) magnetic alloy cores were loaded in the cavity • An independent work on development of a new material, FT3L, is undergoing. J. Pasternak

16. RF development • Substantial progress has been achieved in the design of MA cavities using a new FT3L. • Large-size MA cores have been successfully fabricated at J-PARC. Those cores have two times higher impedance than ordinary FT3M MA cores. • For the PRISM RF system in order to either reduce the core volume cutting the cost by a factor of 3 or to increase the field gradient. • Both options should be considered. J. Pasternak

17. FFAG Ring Choice Scaling Superperiodic Non-Scaling Reference design • We need to decide • about the possible baseline update very soon. • The choice is dictated by the performance. Advanced scaling FFAG See several talks. Advanced NS-FFAG J. Pasternak

18. PRISM Session Programme 1.Recent studies on PRISM muon FFAG, J. Pasternak .2. Beam requirements for PRISM/PRIME, A. Sato.3. Proton beam for PRISM, L. Jenner.4. Front End, J. Pasternak.5. Muon decelerator, A. Alekou.6. Advanced scaling FFAG designs for PRISM, J-B. Lagrange.7. New scaling FDF triplet, D. Kelliher(discussion).8. NS-FFAG design, Y. Shi/J. Pasternak.9. Phase rotation experiment at EMMA (S. Machida/J.Pasternak- discussion).10. Concluding remarks and discussion (All). Please join the session! J. Pasternak